A transmission device of the disclosure includes: a clock signal transmitting circuit that outputs a clock signal onto a clock signal line; a data signal transmitting circuit that outputs a data signal onto a data signal line; and a blanking controller that controls the clock signal transmitting circuit to output a predetermined blanking signal, in place of the clock signal, from the clock signal transmitting circuit to the clock signal line in synchronization with a blanking period of the data signal.
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14. A communication system comprising:
a transmission device that outputs a clock signal onto a clock signal line, outputs a data signal onto a data signal line, and outputs a predetermined blanking signal in place of the clock signal in synchronization with a blanking period of the data signal;
a reception device that receives the data signal through the data signal line, and receives the clock signal and the predetermined blanking signal through the clock signal line; and
an oscillator that supplies the clock signal to the transmission device, wherein
the transmission device includes:
a first single-end signal transmitting circuit that outputs a first single-end signal;
a first transmission switching circuit that switches signal output paths to output one of the clock signal and the first single-end signal onto the clock signal line,
a second single-end signal transmitting circuit that outputs a second single-end signal, and
a second transmission switching circuit that switches signal output paths to output one of the data signal and the second single-end signal onto the data signal line, and
the reception device includes:
a first single-end signal receiving circuit that receives the first single-end signal through the clock signal line,
a first reception switching circuit that switches whether or not to receive the first single-end signal,
a second single-end signal receiving circuit that receives the second single-end signal through the data signal line, and
a second reception switching circuit that switches whether or not to receive the second single-end signal.
12. A reception device comprising:
a data signal receiving circuit that receives a data signal through a data signal line; and
a clock signal receiving circuit that receives a clock signal and a predetermined blanking signal that is outputted in synchronization with a blanking period of the data signal through a clock signal line, wherein
the data signal receiving circuit is a differential data signal receiving circuit that receives a differential data signal as the data signal through the data signal line,
the clock signal receiving circuit is a differential clock signal receiving circuit that receives a differential clock signal as the clock signal and receives, as the predetermined blanking signal, a differential blanking signal that is outputted in such a manner that a predetermined first signal value continues throughout a predetermined period or longer in synchronization with a starting time of the blanking period of the data signal,
the differential data signal receiving circuit has:
a data signal termination circuit including a termination resistor coupled to the data signal line,
the differential clock signal receiving circuit has:
a clock signal termination circuit including a termination resistor coupled to the clock signal line, and
a termination control circuit allowing the data signal termination circuit and the clock signal termination circuit to turn off the respective termination resistors on a basis of the differential blanking signal,
the differential clock signal receiving circuit further receives a differential signal that is different from the differential blanking signal and is outputted in synchronization with an ending time of the blanking period of the data signal through the clock signal line, and
the termination control circuit allows the data signal termination circuit and the clock signal termination circuit to turn on the respective termination resistors on a basis of the predetermined differential signal.
1. A transmission device according comprising:
a clock signal transmitting circuit that outputs a clock signal onto a clock signal line;
a data signal transmitting circuit that outputs a data signal onto a data signal line; and
a blanking controller that controls the clock signal transmitting circuit to output a predetermined blanking signal, in place of the clock signal, from the clock signal transmitting circuit to the clock signal line in synchronization with a blanking period of the data signal, wherein
the clock signal transmitting circuit is a differential clock signal transmitting circuit that outputs a differential clock signal as the clock signal onto the clock signal line,
the data signal transmitting circuit is a differential data signal transmitting circuit that outputs a differential data signal as the data signal onto the data signal line, and
the blanking controller controls the differential clock signal transmitting circuit to output, as the predetermined blanking signal, a differential blanking signal in which a predetermined first signal value continues throughout a predetermined period or longer from the differential clock signal transmitting circuit to the clock signal line in synchronization with a starting time of the blanking period of the data signal, and
the transmission device further comprises:
a first single-end signal transmitting circuit that outputs a first single-end signal;
a first transmission switching circuit that switches signal output paths to allow a signal to be outputted from one of the differential clock signal transmitting circuit and the first single-end signal transmitting circuit to the clock signal line;
a second single-end signal transmitting circuit that outputs a second single-end signal; and
a second transmission switching circuit that switches signal output paths to allow a signal to be outputted from one of the differential data signal transmitting circuit and the second single-end signal transmitting circuit to the data signal line.
2. The transmission device according to
3. The transmission device according to
4. The transmission device according to
5. The transmission device according to
6. The transmission device according to
7. The transmission device according to
8. The transmission device according to
9. The transmission device according to
10. The transmission device according to
11. The transmission device according to
13. The reception device according to
a first single-end signal receiving circuit that receives a first single-end signal through the clock signal line;
a first reception switching circuit that switches whether or not to receive the first single-end signal;
a second single-end signal receiving circuit that receives a second single-end signal through the data signal line; and
a second reception switching circuit that switches whether or not to receive the second single-end signal.
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The disclosure relates to a transmission device, a reception device, a communication system, a signal transmission method, a signal reception method, and a communication method that are all applicable to transmission of data signals and clock signals.
In recent years, the larger-capacity image data has been increasingly handled in a mobile device such as a smartphone, and a camera device, and high-speed performance and low power consumption have been desired for data transmission within a single device or among different devices. To meet such requirements, as connection interfaces intended for the mobile device and the camera device, standardization of the high-speed interface standards such as the C-PHY standard and the D-PHY standard that have been developed by the MIPI (Mobile Industry Processor Interface) alliance has been promoted. The C-PHY standard and the D-PHY standard are interface specifications of a physical layer (Physical Layer: PHY) of a communication protocol. Further, as higher-level protocol layers of the C-PHY standard and the D-PHY standard, a DSI (Display Serial Interface) for a display built into a mobile device, and a CSI (Camera Serial Interface) for a camera device are currently available. PTL 1 proposes a technology that attempts to stabilize signal transmission in accordance with the D-PHY standard.
PTL 1: Japanese Unexamined Patent Application Publication (Published Japanese Translation of PCT Application) No. JP2014-522204
In the C-PHY standard and the D-PHY standard as described above, a high-speed (HS) differential signal is used for transmission of a substantial data signal. Further, in a blanking period of a clock signal and a data signal, a low-power (LP) signal is used. The HS differential signal and the LP signal are transmitted through a common transmission path. For example, in the D-PHY standard, there exist a single transmission path (a clock lane) through which the clock signal is transmitted, and one or more transmission paths (data lanes) through which the data signal is transmitted. A signal transmission period in each of the clock lane and the data lane has a period of transmission with use of the HS differential signal and a period of transmission with use of the LP signal. In each of the clock lane and the data lane, the HS differential signal and the LP signal are transmitted through the common transmission path. However, the LP signal is not a differential signal, but a single-end signal, and a voltage value demanded for signal transmission is different from a voltage value for the HS differential signal. As a result, this necessitates separate circuits for transmission and reception of each of the HS differential signal and the LP signal.
It is therefore desirable to provide a transmission device, a reception device, a communication system, a signal transmission method, a signal reception method, and a communication method that are all able to reduce power consumption for data transmission.
A transmission device according to an embodiment of the disclosure includes: a clock signal transmitting circuit that outputs a clock signal onto a clock signal line; a data signal transmitting circuit that outputs a data signal onto a data signal line; and a blanking controller that controls the clock signal transmitting circuit to output a predetermined blanking signal, in place of the clock signal, from the clock signal transmitting circuit to the clock signal line in synchronization with a blanking period of the data signal.
A reception device according to an embodiment of the disclosure includes: a data signal receiving circuit that receives a data signal through a data signal line; and a clock signal receiving circuit that receives a clock signal and a predetermined blanking signal that is outputted in synchronization with a blanking period of the data signal through a clock signal line.
A communication system according to an embodiment of the disclosure includes: a transmission device that outputs a clock signal onto a clock signal line, outputs a data signal onto a data signal line, and outputs a predetermined blanking signal in place of the clock signal in synchronization with a blanking period of the data signal; and a reception device that receives the data signal through the data signal line, and receives the clock signal and the predetermined blanking signal through the clock signal line.
A signal transmission method according to an embodiment of the disclosure includes: outputting a clock signal onto a clock signal line; outputting a data signal onto a data signal line; and outputting a predetermined blanking signal, in place of the clock signal, onto the clock signal line in synchronization with a blanking period of the data signal.
A signal reception method according to an embodiment of the disclosure includes: receiving a data signal through a data signal line; and receiving a clock signal and a predetermined blanking signal that is outputted in synchronization with a blanking period of the data signal through a clock signal line.
A communication method according to an embodiment of the disclosure includes: outputting a clock signal onto a clock signal line; outputting a data signal onto a data signal line; outputting a predetermined blanking signal, in place of the clock signal, onto the clock signal line in synchronization with a blanking period of the data signal; receiving the data signal through the data signal line; and receiving the clock signal and the predetermined blanking signal through the clock signal line.
In the transmission device or the communication system, or the signal transmission method or the communication method according to the embodiment of the disclosure, the predetermined blanking signal is outputted in place of the clock signal onto the clock signal line in synchronization with the blanking period of the data signal.
In the reception device or the communication system, or the signal reception method or the communication method according to the embodiment of the disclosure, the clock signal and the predetermined blanking signal that is outputted in synchronization with the blanking period of the data signal are received through the clock signal line.
According to the transmission device or the communication system, or the signal transmission method or the communication method of the embodiment of the disclosure, the predetermined blanking signal is outputted in place of the clock signal onto the clock signal line in synchronization with the blanking period of the data signal, which makes it possible to reduce power consumption for data transmission.
According to the reception device or the communication system, or the signal reception method or the communication method of the embodiment of the disclosure, the clock signal and the predetermined blanking signal that is outputted in synchronization with the blanking period of the data signal are received through the clock signal line, which makes it possible to reduce power consumption for data transmission.
It is to be noted that the effects of the disclosure are not necessarily limited to the effects described here, and may be one or more of effects described in the disclosure.
Hereinafter, embodiments of the disclosure are described in detail with reference to the drawings. It is to be noted that description is given in the following order.
0. Communication System Using LP Signal and HS Differential Signal (Comparative Example) (
1. First Embodiment (First Example of Communication System Using Only HS Differential Signal) (
2. Second Embodiment (Second Example of Communication System Using Only HS Differential Signal)
2.1 Configuration and Operation (
2.2 Modification Examples (
3. Third Embodiment (Communication System Allowing for Switchover between Two Communication Modes) (
4. Fourth Embodiment (Communication System Omitting Termination Control) (
5. Application Examples
5.1 First Application Example (
5.2 Second Application Example (
6. Other Embodiments
Prior to description of a communication system according to embodiments, an overview of a communication system using an LP signal and an HS differential signal is first described as a comparative example.
The transmitter TX includes a transmission digital circuit TX-DIGITAL and a transmission analog circuit TX-ANALOG For example, a 16-bit or 8-bit parallel signal is transmitted between the transmission digital circuit TX-DIGITAL and the transmission analog circuit TX-ANALOG
The receiver RX includes a reception digital circuit RX-DIGITAL and a reception analog circuit RX-ANALOG On each of the data lanes DL1, DL2, DL3, and DL4, for example, a 16-bit or 8-bit parallel signal is transmitted between the reception analog circuit RX-ANALOG and the reception digital circuit RX-DIGITAL. On the clock lane CL, for example, a 2-bit serial signal is transmitted between the reception analog circuit RX-ANALOG and the reception digital circuit RX-DIGITAL.
On the clock lane CL, coupling is made between the transmission analog circuit TX-ANALOG and the reception analog circuit RX-ANALOG through a clock signal line 30 that allows a differential clock signal to be transmitted therethrough. On the data lanes DL1, DL2, DL3, and DL4, coupling is made between the transmission analog circuit TX-ANALOG and the reception analog circuit RX-ANALOG through data signal lines 31, 32, 33, and 34, respectively, that allow differential data signals to be transmitted therethrough. Each of the clock signal line 30 and the data signal lines 31, 32, 33, and 34 has a pair of a positive signal line Dp and a negative signal line Dn through which differential signals are transmitted. For example, a 2-bit serial signal is transmitted through each of the clock signal line 30 and the data signal lines 31, 32, 33, and 34.
The communication system according to the comparative example includes a transmitter 101 corresponding to the transmitter TX in
On the clock lane CL, the transmitter 101 includes a CL-HS circuit 111 that processes the HS differential signal, and a CL-LP circuit 112 that processes the LP signal. On the data lane DL1, the transmitter 101 includes a DL-HS circuit 113 that processes the HS differential signal, and a DL-LP circuit 114 that processes the LP signal.
On the clock lane CL, the receiver 102 includes a CL-HS circuit 121 that processes the HS differential signal, and a CL-LP circuit 122 that processes the LP signal. On the data lane DL1, the receiver 102 includes a DL-HS circuit 123 that processes the HS differential signal, and a DL-LP circuit 124 that processes the LP signal.
As illustrated in
In a similar manner, on the data lane DL1, a status of a signal to be outputted onto the data signal line 31 from the transmitter 101 has the HPS period in which the signal is put in a state of being transmitted in the form of the HS differential signal, and the LPS period in which the signal is put in a state of being transmitted in the form of the LP signal. A substantial data signal is outputted in the form of the HS differential signal in the HPS period. It is to be noted that a portion of the substantial data signal is denoted as HST in
As illustrated in
The CL-HS circuit 111 includes an HS state machine (HS FSM) 51, a selector 52, a parallel/serial (PS) conversion circuit 53, a clock divider (DIV) 54, and an HS driver (HS DRV) 55. The selector 52 selectively outputs a Toggle signal, a signal with a value of 0 (ALL0), and a signal with a value of 1 (ALL1). The Toggle signal is, for example, an 8-bit clock signal (1010_1010).
The CL-LP circuit 112 includes an LP state machine (LP FSM) 41, an LP encoder (LP ENC) 42, and an LP driver (LP DRV) 43. A clock lane control signal is inputted to the LP state machine 41.
The DL-HS circuit 113 includes an HS state machine (HS FSM) 71, a selector 72, a parallel/serial (PS) conversion circuit 73, and an HS driver (HS DRV) 74. A data transmission ready signal TxReadyHS is outputted from the HS state machine 71. The selector 72 selectively outputs a transmission data TxDataHS, a synchronization code signal SYNC, the signal with a value of 0 (ALL0), and the signal with a value of 1 (ALL1).
The DL-LP circuit 114 includes an LP state machine (LP FSM) 61, an LP encoder (LP ENC) 62, and an LP driver (LP DRV) 63. A data transmission request signal TxRequestHS is inputted to the LP state machine 61.
It is to be noted that, in the transmitter 101, the LP driver 43, the HS driver 55, the LP driver 63, and the HS driver 74 correspond to the transmission analog circuit TX-ANALOG in
The CL-HS circuit 121 includes a termination circuit (TERM) 56 that serves as a clock signal termination circuit, an HS receiver (HS RCV) 57, and a clock divider (DIV) 58. The termination circuit 56 has a termination resistor.
The CL-LP circuit 122 includes an LP receiver (LP RCV) 44, an LP decoder (LP DEC) 45, and an LP state machine (LP FSM) 46. The LP state machine 46 outputs a status signal of the clock lane CL.
The DL-HS circuit 123 includes a termination circuit (TERM) 75 that serves as a data signal termination circuit, an HS receiver (HS RCV) 76, a clock divider (DIV) 77, and a word alignment correction circuit (ALN) 78. The termination circuit 75 has a termination resistor. The word alignment correction circuit (ALN) 78 outputs a reception synchronization signal RxSyncHS, a reception valid signal RxValidHS, and reception data RxDataHS.
The DL-LP circuit 124 includes an LP receiver (LP RCV) 64, an LP decoder (LP DEC) 65, and an LP state machine (LP FSM) 66. The LP state machine 66 outputs a reception active signal RxActiveHS.
It is to be noted that, in the receiver 102, primarily the LP receiver 44, the termination circuit 56, the HS receiver 57, the LP receiver 64, the termination circuit 75, and the HS receiver 76 correspond to the reception analog circuit RX-ANALOG in
Next, description is provided on a first embodiment of the disclosure. Hereinafter, description of configurations and workings substantially similar to those in the foregoing comparative example is omitted as appropriate.
The communication system according to the present embodiment includes a transmitter 1 (a transmission device) corresponding to the transmitter TX in
As illustrated in
It is to be noted that HS-0 indicates a differential signal with a value of 0 (differential 0 (Differential-0)), and HS-1 indicates a differential signal with a value of 1 (differential 1 (Differential-1)). More specifically, as represented in
Similarly, on the data lane DL1, all signals to be outputted onto the data signal line 31 from the transmitter 1 including the blanking period are only the HS differential signals.
It is to be noted that, in
As illustrated in
On the clock lane CL, the transmitter 1 includes a CL-HS circuit 11 that processes the HS differential signal. On the data lane DL1, the transmitter 1 includes a DL-HS circuit 13 that processes the HS differential signal.
The CL-HS circuit 11 may be also a differential clock signal transmitting circuit that outputs the HS differential signal including the differential clock signal onto the clock signal line 30. The DL-HS circuit 13 may be also a differential data signal transmitting circuit that outputs the differential data signal onto the data signal line 31.
The transmitter 1 in the present embodiment may not include circuits corresponding to the CL-LP circuit 112 and the DL-LP circuit 114 that process the LP signal in the above-described comparative example.
The CL-HS circuit 11 may include a circuit that is substantially similar to the CL-HS circuit 111 in
The DL-HS circuit 13 may include a circuit that is substantially similar to the DL-HS circuit 113 in
The transmitter 1 includes a blanking controller 20. The blanking controller 20 may include the HS state machine 51 and the HS state machine 71, as illustrated in
The blanking controller 20 controls the DL-HS circuit 13 so as to output a predetermined data blanking signal, in place of the data signal, from the DL-HS circuit 13 to the data signal line 31 in synchronization with a starting time of the blanking period of the data signal. Further, the blanking controller 20 controls the CL-HS circuit 11 so as to output a differential blanking signal in which the predetermined first signal value (for example, HS-0) continues throughout a predetermined period or longer, in place of the clock signal, from the CL-HS circuit 11 to the clock signal line 30 in synchronization with the starting time of the blanking period of the data signal. Here, the predetermined period refers to a period that is longer than a clock cycle of the clock signal. The differential blanking signal is a signal in which the predetermined first signal value continues throughout a period longer than the clock cycle of the clock signal, which makes it possible to detect a signal variation in a clock state discrimination circuit 59 in the receiver 2 to be described later, thereby detecting starting of the blanking period.
Further, the blanking controller 20 controls the CL-HS circuit 11 so as to output a predetermined differential signal different from the differential blanking signal, in place of the differential blanking signal, from the CL-HS circuit 11 to the clock signal line 30 in synchronization with an ending time of the blanking period of the data signal. Specifically, the blanking controller 20 controls the CL-HS circuit 11 so as to output, as the predetermined differential signal, a differential signal in which the predetermined second signal value (for example, HS-1) different from the predetermined first signal value continues throughout the predetermined period or longer. It is to be noted that the predetermined first signal value in the above description may be HS-1, and the predetermined second signal values may be HS-0. The predetermined differential signal is a differential signal in which the predetermined second signal value different from the predetermined first signal value continues throughout the predetermined period or longer, which makes it possible to detect a signal variation in the clock state discrimination circuit 59 in the receiver 2 to be described later, thereby detecting ending of the blanking period and starting of transfer of the data signal.
On the clock lane CL, the receiver 2 includes a CL-HS circuit 21 that processes the HS differential signal. On the data lane DL1, the receiver 2 includes a DL-HS circuit 23 that processes the HS differential signal.
The DL-HS circuit 23 may be also a differential data signal receiving circuit that receives the differential signal through the data signal line 31. The CL-HS circuit 21 may be also a differential clock signal receiving circuit that receives the differential clock signal and the differential blanking signal that is outputted from the above-described CL-HS circuit 11 through the clock signal line 30.
The receiver 2 in the present embodiment may not include circuits corresponding to the CL-LP circuit 122 and the DL-LP circuit 124 that process the LP signal in the above-described comparative example.
The DL-HS circuit 23 may include a circuit that is substantially similar to the DL-HS circuit 123 in
The CL-HS circuit 21 may include a circuit that is substantially similar to the CL-HS circuit 121 in
The CL-HS circuit 21 further includes the clock (CL) state discrimination circuit 59. The clock state discrimination circuit 59 receives the clock signal incoming from the CL-HS circuit 11 of the transmitter 1 through the HS receiver 57, the differential blanking signal (for example, HS-0) with the predetermined first signal value (for example, HS-0), and the differential signal with the predetermined second signal value (for example, HS-1).
The clock state discrimination circuit 59 has a function as a termination control circuit, and controls a data signal termination circuit (the termination circuit 75) and a clock signal termination circuit (the termination circuit 56) to turn off respective termination resistors on the basis of the differential blanking signal. Further, the clock state discrimination circuit 59 controls the termination circuit 75 and the termination circuit 56 to turn on the respective termination resistors on the basis of the differential signal with the predetermined second signal value (for example, HS-1) that is outputted in synchronization with the ending time of the blanking period of the data signal.
It is to be noted that, in association with on/off switching of the termination resistors, a signal voltage amplitude varies in the blanking period on each of the clock lane CL and the data lane DL1, as illustrated in
Further, the clock state discrimination circuit 59 has a function of outputting the reception active signal RxActiveHS and performing word alignment control for the word alignment correction circuit 78. The clock state discrimination circuit 59 properly detects ending of the blanking period and starting of transfer of the data signal, which makes it possible to detect the synchronization code signal SYNC, and to perform the word alignment control with use of the word alignment correction circuit 78.
[Effects]
As described above, according to the present embodiment, the differential blanking signal in which the predetermined first signal value continues throughout the predetermined period or longer is outputted, in place of the clock signal, onto the clock signal line 30 in synchronization with the starting time of the blanking period of the data signal, which makes it possible to reduce power consumption for data transmission.
In addition, the differential clock signal, and the differential blanking signal in which the predetermined first signal value continues throughout the predetermined period or longer and that is outputted in synchronization with the starting time of the blanking period of the data signal are received through the clock signal line 30, which makes it possible to reduce power consumption for data transmission.
Further, according to the present embodiment, it is possible to transfer the data signal with use of the HS differential signal to a LP signal portion (the blanking period) as well that is not used effectively in the communication system according to the above-described comparative example. This makes it possible to lower a transfer rate of the data signal with use of the HS differential signal, thereby achieving low power consumption as a whole. In addition, according to the present embodiment, the necessity of a circuit for processing the LP signal is eliminated, which makes it possible to reduce a circuit size, in comparison with the communication system according to the above-described comparative example.
It is to be noted that the effects described herein are merely exemplified and non-limiting, and effects achieved by the technology may be effects other than those described herein. The same is true for effects of the following other embodiments.
Next, description is provided on a second embodiment of the disclosure. Hereinafter, description of configurations and workings substantially similar to those in the foregoing comparative example and the above-described first embodiment is omitted as appropriate.
In the present embodiment as well, as with the above-described first embodiment, the blanking controller 20 controls the CL-HS circuit 11 so as to output a predetermined differential signal different from the differential blanking signal, in place of the differential blanking signal, from the CL-HS circuit 11 to the clock signal line 30 in synchronization with the ending time of the blanking period of the data signal. In the above-described first embodiment, the blanking controller 20 controls the CL-HS circuit 11 so as to output, as the predetermined differential signal, a differential signal in which the predetermined second signal value (for example, HS-1) continues throughout the predetermined period or longer. In contrast, in the present embodiment, the blanking controller 20 controls the CL-HS circuit 11 so as to output the clock signal as the predetermined differential signal throughout the predetermined period or longer. The predetermined differential signal is the clock signal that is outputted throughout the predetermined period or longer, which makes it possible to detect a signal variation in the clock state discrimination circuit 59 in the receiver 2, thereby detecting ending of the blanking period and starting of transfer of the data signal.
In the present embodiment, on the clock lane CL, in the blanking period, the differential blanking signal with the predetermined first signal value (for example, HS-0 or HS-1), and the clock signal are outputted from the transmitter 1 to the clock signal line 30, as illustrated in
As compared with a circuit configuration in
Other configurations and operation may be substantially similar to those of the communication system according to the above-described first embodiment.
Next, description is provided on first to fifth modification examples of the communication system according to the second embodiment.
Each of
In the first modification example illustrated in
The blanking controller 20 controls the DL-HS circuit 13 so as to output a differential signal having an inverted value of the last value of the data signal from the DL-HS circuit 13 to the data signal line 31 in synchronization with the starting time of the blanking period. Further, the blanking controller 20 controls the DL-HS circuit 13 so as to output a differential signal of HS-0, in place of the differential signal having an inverted value of the last value of the data signal, from the DL-HS circuit 13 to the data signal line 31 in synchronization with the ending time of the blanking period. It is to be noted that, as with the example in
According to the first modification example, by outputting the differential signal of HS-0 in the last period of the blanking period on the data lane DL1, a signal value in the last period of the blanking period and a signal value at the beginning of the subsequent SYNC (synchronization) period THS-SYNC are made to be identical to each other, which makes it possible to facilitate synchronization processing on the reception side. Further, a signal in the TRIAL period THS-TRIAL on the data lane DL1 is typically a differential signal having an inverted value of the last value of the data signal. Therefore, according to the first modification example, it is possible to match a signal value at the beginning of the blanking period to the signal in the TRIAL period THS-TRIAL.
The signal waveform in the present modification example may be substantially similar to the signal waveform in
In the second modification example illustrated in
According to the second modification example, as compared with the case where the termination resistors are turned on during an output period of the clock signal as in the first modification example, it is possible to reduce an influence of waveform disturbance that is caused by reflection of the clock signal in an off state of the termination resistors in the clock lane CL.
The present modification example may be substantially similar to the first modification example in
In the third modification example illustrated in
The present modification example may be substantially similar to the second modification example in
In the fourth modification example illustrated in
The present modification example may be substantially similar to the first modification example in
In the fifth modification example illustrated in
The present modification example may be substantially similar to the second modification example in
Next, description is provided on a third embodiment of the disclosure. Hereinafter, description of configurations and workings substantially similar to those in the foregoing comparative example, the above-described first embodiment, and the above-described second embodiment is omitted as appropriate.
In the communication systems according to the above-described first and second embodiments, all signals to be transmitted on each of the clock lane CL and the data lane DL1 including the blanking period are only the HS differential signals. In contrast, the communication system according to the present embodiment includes a switching circuit that enables communication using the LP signal as well, allowing for switchover between a mode of performing communication using only the HS differential signal without using the LP signal and a mode of performing communication using both the LP signal and the HS differential signal.
In the communication system according to the present embodiment, the transmitter 1B includes the blanking controller 20 that achieves a function that is substantially similar to the function of each of the communication systems according to the above-described first and second embodiments.
Moreover, on the clock lane CL, the transmitter 1B further includes the CL-HS circuit 11 that processes the HS differential signal, a CL-LP circuit 12 that processes the LP signal, a changeover switch 15, and a selector 17.
The CL-LP circuit 12 may be a first single-end signal transmitting circuit that outputs a first single-end signal as the LP signal. The CL-LP circuit 12 may have a function that is substantially similar to the function of the CL-LP circuit 112 in
On the data lane DL1, the transmitter 1B further includes the DL-HS circuit 13 that processes the HS differential signal, a DL-LP circuit 14 that processes the LP signal, a changeover switch 16, and a selector 18.
The DL-LP circuit 14 may be a second single-end signal transmitting circuit that outputs a second single-end signal as the LP signal. The DL-LP circuit 14 may have a function that is substantially similar to the function of the DL-LP circuit 114 in
On the clock lane CL, the receiver 2B includes the CL-HS circuit 21 that processes the HS differential signal, a CL-LP circuit 22 that processes the LP signal, a selector 25, a selector 27, and a selector 28. The CL-LP circuit 22 may be a first single-end signal receiving circuit that receives a first single-end signal as the LP signal through the clock signal line 30. The CL-LP circuit 22 may have a function that is substantially similar to the function of the CL-LP circuit 122 in
The selector 25 may be a first reception switching circuit that switches whether or not to receive the first single-end signal as the LP signal. The selector 25 is a circuit that allows a signal received through the clock signal line 30 not o be inputted to the CL-LP circuit 22 in the mode of performing communication using only the HS differential signal without using the LP signal and allows the signal received through the clock signal line 30 to be inputted to the CL-LP circuit 22 in the mode of performing communication using both the LP signal and the HS differential signal. The selector 27 is a circuit that allows a termination control signal from the CL-HS circuit 21 to be inputted to the DL-HS circuit 23 in the mode of performing communication using only the HS differential signal without using the LP signal and allows the termination control signal from the CL-HS circuit 21 not to be inputted to the DL-HS circuit 23 in the mode of performing communication using both the LP signal and the HS differential signal. The selector 28 is a circuit that allows a word alignment control signal from the CL-HS circuit 21 to be inputted to the DL-HS circuit 23 in the mode of performing communication using only the HS differential signal without using the LP signal and allows the word alignment control signal from the CL-HS circuit 21 not to be inputted to the DL-HS circuit 23 in the mode of performing communication using both the LP signal and the HS differential signal.
On the data lane DL1, the receiver 2B further includes the DL-HS circuit 23 that processes the HS differential signal, a DL-LP circuit 24 that processes the LP signal, and a selector 26. The DL-LP circuit 24 may be a second single-end signal receiving circuit that receives a second single-end signal as the LP signal through the data signal line 31.
The selector 26 may be a second reception switching circuit that switches whether or not to receive the second single-end signal as the LP signal. The selector 26 is a circuit that allows a signal received through the data signal line 31 not to be inputted to the DL-LP circuit 24 in the mode of performing communication using only the HS differential signal without using the LP signal and allows the signal received through the data signal line 31 to be inputted to the DL-LP circuit 24 in the mode of performing communication using both the LP signal and the HS differential signal.
For example, the communication system according to the present embodiment is applicable to data transmission from an image sensor IS to an application processor AP, as illustrated in
Moreover, coupling is made between the image sensor IS and the application processor AP through a bidirectional control bus 35. As the control bus 35, it is possible to use an I2C (Inter-Integrated Circuit) interface and an I3C interface as an extended version of the I2C interface.
When the apparatus incorporating the image sensor IS and the application processor AP is powered on (step S101), the application processor AP reads register settings of the image sensor IS using the control bus 35 (step S102). In such a manner, the application processor AP determines whether or not the image sensor IS is compatible with communication without using the LP signal (step S103). In other words, the application processor AP determines whether the image sensor IS is compatible with either the mode of performing communication using only the HS differential signal without using the LP signal or the mode of performing communication using both the LP signal and the HS differential signal.
In a case where the application processor AP determines that the image sensor IS is compatible with the communication without using the LP signal (step S103: Y), the application processor AP sends setting of enabling the communication without using the LP signal to the image sensor IS using the control bus 35 (step S104). Next, the application processor AP outputs a signal indicating start of transmission to the image sensor IS using the control bus 35 (step S105). In a case where the application processor AP determines that the image sensor IS is not compatible with the communication without using the LP signal (step S103: N), the application processor AP considers that the image sensor IS is compatible with the mode of performing communication using both the LP signal and the HS differential signal, and outputs a signal indicating start of transmission to the image sensor IS using the control bus 35 (step S105). Next, the image sensor IS starts transmission of the data signal upon reception of the signal indicating start of transmission (step S106).
Next, description is provided on a fourth embodiment of the disclosure. Hereinafter, description of configurations and workings substantially similar to those in the foregoing comparative example and the above-described first to third embodiments is omitted as appropriate.
The communication system according to the present embodiment is different in a portion of termination control from a configuration of the communication system as illustrated in
The first example in
Further, the second example in
The first example in
The signal waveform in the present embodiment may be substantially similar to the signal waveform in
Next, description is provided on application examples of the communication system described in each of the above-described embodiments.
The CPU 311 processes various information to be handled in the smartphone 300 in accordance with programs. The memory controller 312 controls a memory 501 to be used by the CPU 311 for information processing operation. The power source controller 313 controls a power source of the smartphone 300.
The external interface 314 is an interface for communication with external devices, and is coupled to a wireless communication section 502 and an image sensor 410 in this example. The wireless communication section 502 performs wireless communication with mobile phone base stations, and includes, for example, a baseband section, an RF (Radio Frequency) front-end section, and any other section. The image sensor 410 acquires an image, and includes, for example, a CMOS sensor.
The GPU 315 carries out image processing operation. The media processor 316 processes information such as voice, characters, and graphics. The display controller 317 controls a display 504 through the MIPI interface 318.
The MIPI interface 318 transmits image signals to the display 504. As such image signals, it is possible to use, for example, signals of YUV format, RGB format, and other format. For example, the communication system according to any of the above-described embodiments is applicable to a communication system between the MIPI interface 318 and the display 504.
The sensor section 411 acquires an image, and includes, for example, a CMOS sensor. The ISP 412 performs predetermined processing operation for the image acquired by the sensor section 411. The JPEG encoder 413 encodes the image processed by the ISP 412 to generate a JPEG-format image. The CPU 414 controls each block of the image sensor 410 in accordance with a program. The RAM 415 is a memory to be used by the CPU 414 for information processing operation. The ROM 416 stores programs to be executed in the CPU 414. The power source controller 417 controls a power source of the image sensor 410. The I2C interface 418 receives a control signal from the application processor 310. Further, although not illustrated, the image sensor 410 also receives a clock signal from the application processor 310 in addition to the control signal. Specifically, the image sensor 410 is configured to be operable on the basis of clock signals at various frequencies.
The MIPI interface 419 transmits image signals to the application processor 310. As such image signals, it is possible to use, for example, signals of the YUV format, the RGB format, and other format. For example, the communication system according to any of the above-described embodiments is applicable to a communication system between the MIPI interface 419 and the application processor 310.
Each of
For example, on-vehicle camera 401, 402, 403, and 404 are respectively mounted on the front (forward), left, right, and rear (backward) of a vehicle 301, as illustrated in
An image-capturing angle of the on-vehicle camera 401 mounted on the front of the vehicle 301 is, for example, in a range indicated with “a” in
For example, each of the on-vehicle cameras 401 to 404 includes an image sensor 431, a DSP (Digital Signal Processing) circuit 432, a selector 433, and a SerDes (SERializer/DESerializer) circuit 444, as illustrated in
The DSP circuit 432 performs a variety of image signal processing operation for an imaging signal outputted from the image sensor 431. The SerDes circuit 444 performs serial/parallel conversion of a signal, and includes an on-vehicle interface chip such as FDP-Link III, for example.
The selector 433 selects whether to output the imaging signal outputted from the image sensor 431 through the DSP circuit 432, or not through the DSP circuit 432.
For example, the communication system according to any of the above-described embodiments is applicable to a coupling interface 441 between the image sensor 431 and the DSP circuit 432. Further, for example, the communication system according to any of the above-described embodiments is applicable to a coupling interface 442 between the image sensor 431 and the selector 433.
The technology achieved by the disclosure is not limited to that described in the above-described respective embodiments, and may be modified in a variety of ways.
For example, the technology may be configured as follows.
(1)
A transmission device including:
a clock signal transmitting circuit that outputs a clock signal onto a clock signal line;
a data signal transmitting circuit that outputs a data signal onto a data signal line; and
a blanking controller that controls the clock signal transmitting circuit to output a predetermined blanking signal, in place of the clock signal, from the clock signal transmitting circuit to the clock signal line in synchronization with a blanking period of the data signal.
(2)
The transmission device according to (1), in which
the clock signal transmitting circuit is a differential clock signal transmitting circuit that outputs a differential clock signal as the clock signal onto the clock signal line,
the data signal transmitting circuit is a differential data signal transmitting circuit that outputs a differential data signal as the data signal onto the data signal line, and
the blanking controller controls the differential clock signal transmitting circuit to output, as the predetermined blanking signal, a differential blanking signal in which a predetermined first signal value continues throughout a predetermined period or longer from the differential clock signal transmitting circuit to the clock signal line in synchronization with a starting time of the blanking period of the data signal.
(3)
The transmission device according to (2), in which the predetermined period is a longer period than a clock cycle of the clock signal.
(4)
The transmission device according to (2) or (3), in which the blanking controller controls the differential clock signal transmitting circuit to output a predetermined differential signal different from the differential blanking signal, in place of the differential blanking signal, from the differential clock signal transmitting circuit to the clock signal line in synchronization with an ending time of the blanking period of the data signal.
(5)
The transmission device according to (4), in which the blanking controller controls the differential clock signal transmitting circuit to output, as the predetermined differential signal, a differential signal in which a predetermined second signal value different from the predetermined first signal value continues throughout the predetermined period or longer from the differential clock signal transmitting circuit to the clock signal line.
(6)
The transmission device according to (4), in which the blanking controller controls the differential clock signal transmitting circuit to output the clock signal as the predetermined differential signal from the differential clock signal transmitting circuit to the clock signal line throughout the predetermined period or longer.
(7)
The transmission device according to (5), in which after a signal with the predetermined second signal value is outputted, the blanking controller controls the differential clock signal transmitting circuit to output the clock signal from the differential clock signal transmitting circuit to the clock signal line in the blanking period. The transmission device according to (4).
(8)
The transmission device according to any one of (2) to (7), in which the blanking controller further controls the data signal transmitting circuit to output at least a predetermined data blanking signal, in place of the data signal, from the data signal transmitting circuit to the data signal line in synchronization with the starting time of the blanking period of the data signal.
(9)
The transmission device according to (8), in which the blanking controller controls the data signal transmitting circuit to output, as the predetermined data blanking signal, a signal having an inverted value of a last signal value of the data signal.
(10)
The transmission device according to (8), in which the blanking controller controls the differential data signal transmitting circuit to output, as the predetermined data blanking signal, a differential signal with a value of 1.
(11)
The transmission device according to (8), in which after the predetermined data blanking signal is outputted, the blanking controller controls the differential data signal transmitting circuit to output a differential signal with a value of 0 in synchronization with an ending time of the blanking period of the data signal.
(12)
The transmission device according to (8), in which the blanking controller controls the differential data signal transmitting circuit to output a differential signal with a value of 0 throughout the whole blanking period as the predetermined data blanking signal.
(13)
The transmission device according to any one of (2) to (12), further including:
a first single-end signal transmitting circuit that outputs a first single-end signal;
a first transmission switching circuit that switches signal output paths to allow a signal to be outputted from one of the differential clock signal transmitting circuit and the first single-end signal transmitting circuit to the clock signal line;
a second single-end signal transmitting circuit that outputs a second single-end signal; and
a second transmission switching circuit that switches signal output paths to allow a signal to be outputted from one of the differential data signal transmitting circuit and the second single-end signal transmitting circuit to the data signal line.
(14)
A reception device including:
a data signal receiving circuit that receives a data signal through a data signal line; and
a clock signal receiving circuit that receives a clock signal and a predetermined blanking signal that is outputted in synchronization with a blanking period of the data signal through a clock signal line.
(15)
The reception device according to (14), in which
the data signal receiving circuit is a differential data signal receiving circuit that receives a differential data signal as the data signal through the data signal line, and
the clock signal receiving circuit is a differential clock signal receiving circuit that receives a differential clock signal as the clock signal and receives, as the predetermined blanking signal, a differential blanking signal that is outputted in such a manner that a predetermined first signal value continues throughout a predetermined period or longer in synchronization with a starting time of the blanking period of the data signal.
(16)
The reception device according to (15), in which
the differential data signal receiving circuit has:
a data signal termination circuit including a termination resistor coupled to the data signal line, and
the differential clock signal receiving circuit has:
a clock signal termination circuit including a termination resistor coupled to the clock signal line, and
a termination control circuit allowing the data signal termination circuit and the clock signal termination circuit to turn off the respective termination resistors on a basis of the differential blanking signal.
(17)
The reception device according to (16), in which
the differential clock signal receiving circuit further receives a differential signal that is different from the differential blanking signal and is outputted in synchronization with an ending time of the blanking period of the data signal through the clock signal line, and
the termination control circuit allows the data signal termination circuit and the clock signal termination circuit to turn on the respective termination resistors on a basis of the predetermined differential signal.
(18)
The reception device according to any one of (15) to (17), further including:
a first single-end signal receiving circuit that receives a first single-end signal through the clock signal line;
a first reception switching circuit that switches whether or not to receive the first single-end signal;
a second single-end signal receiving circuit that receives a second single-end signal through the data signal line; and
a second reception switching circuit that switches whether or not to receive the second single-end signal.
(19)
A communication system including:
a transmission device that outputs a clock signal onto a clock signal line, outputs a data signal onto a data signal line, and outputs a predetermined blanking signal in place of the clock signal in synchronization with a blanking period of the data signal; and
a reception device that receives the data signal through the data signal line, and receives the clock signal and the predetermined blanking signal through the clock signal line.
(20)
The communication system according to (19), further including an oscillator that supplies the clock signal to the transmission device.
(21)
The communication system according to (19) or (20), in which
the transmission device includes:
a first single-end signal transmitting circuit that outputs a first single-end signal;
a first transmission switching circuit that switches signal output paths to output one of the clock signal and the first single-end signal onto the clock signal line,
a second single-end signal transmitting circuit that outputs a second single-end signal, and
a second transmission switching circuit that switches signal output paths to output one of the data signal and the second single-end signal onto the data signal line, and
the reception device includes:
a first single-end signal receiving circuit that receives the first single-end signal through the clock signal line,
a first reception switching circuit that switches whether or not to receive the first single-end signal,
a second single-end signal receiving circuit that receives the second single-end signal through the data signal line, and
a second reception switching circuit that switches whether or not to receive the second single-end signal.
(22)
A signal transmission method including:
outputting a clock signal onto a clock signal line;
outputting a data signal onto a data signal line; and
outputting a predetermined blanking signal, in place of the clock signal, onto the clock signal line in synchronization with a blanking period of the data signal.
(23)
A signal reception method including:
receiving a data signal through a data signal line; and
receiving a clock signal and a predetermined blanking signal that is outputted in synchronization with a blanking period of the data signal through a clock signal line.
(24)
A communication method including:
outputting a clock signal onto a clock signal line;
outputting a data signal onto a data signal line;
outputting a predetermined blanking signal, in place of the clock signal, onto the clock signal line in synchronization with a blanking period of the data signal;
receiving the data signal through the data signal line; and
receiving the clock signal and the predetermined blanking signal through the clock signal line.
This application claims the priority on the basis of Japanese Patent Application No. 2015-120465 filed on Jun. 15, 2015 and Japanese Patent Application No. 2015-205599 filed on Oct. 19, 2015 with Japan Patent Office, the entire contents of which are incorporated in this application by reference.
It should be understood by those skilled in the art that various modifications, combinations, sub-combinations, and alterations may occur depending on design requirements and other factors insofar as they are within the scope of the appended claims or the equivalents thereof.
Matsumoto, Hideyuki, Takahashi, Hiroo, Hayashi, Hiroaki, Koshisaka, Naohiro
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